Highlights

• China controls 37% of global rare earth element reserves and 80% of global processing capacity, giving it unprecedented technological and economic power.
• Rare earth elements are critical to modern technology, from smartphones and electric vehicles to defense systems, with the global market projected to reach $10.9 billion by 2029.
• China's rare earth industry faces environmental challenges while simultaneously investing in green mining, recycling technologies, and maintaining strategic global market control.

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In the deep seams of Chinese soil and the quiet clays of its southern hills lies a story that touches your smartphone, your car, the wind turbine on a faraway ridge, and even the defense systems that guard nations. This is the story of rare earth elements—17 metallic cousins so alike in chemistry that the world once mistook them for a single mineral curiosity. Today, they are the lifeblood of modern technology, and China is their undisputed master.

By 2024, the global rare earth metals market is worth USD 6.0 billion and climbing fast toward USD 10.9 billion by 2029. Yet unlike copper or gold, REEs rarely grace public commodity markets. They move quietly—producer to supplier—into magnets, lasers, batteries, and catalysts that keep 21st-century life humming.

The Kingdom Below: China’s Reserves and Mines

China sits atop about 44 million metric tons of these elements—37% of the planet’s known reserves—spread like buried treasure across six great regions.

Region	Summary
Bayan Obo, Inner Mongolia	A vast open wound in the earth, this is the world’s largest REE deposit, yielding 70% of China’s output. Its ores brim with neodymium, praseodymium, and lanthanum—metals that make magnets spin and catalysts crack oil.
Sichuan Province	Bastnäsite-rich hills feeding high-tech motors and turbines.
Shandong Province	Monazite sands that polish glass and strengthen steel.
Jiangxi, Guangdong, Fujian	Gentle green hills hiding ion-adsorption clays, rich in dysprosium, terbium, and yttrium—metals that keep magnets strong in high heat and phosphors glowing in screens.

Each region uses its own mining script. Open pits strip forests and topsoil for easy ore. In-situ leaching slips chemicals underground to coax REEs to the surface—less scarring to the land, but a gamble with groundwater. Underground mines keep the surface intact, but demand money and engineering skill.

In 2024, these mines gave China 60% of the world’s rare earth ore. More importantly, the country holds 80% of refining capacity—the real choke point of the industry.

The Alchemy of Processing—and the Grip It Gives

Digging REEs from the earth is only the first act. The transformation—turning mixed ore into a handful of pure elements—requires complex chemistry, meticulous separation, and sometimes dangerous handling of radioactive by-products. Here, China’s dominance is absolute: ~90% of global processing capacity sits within its borders.

Why China leads

decades of investment in solvent extraction and ion-exchange chromatography; a workforce with what was traditionally lower labor costs; abundant, cheap electricity; sprawling industrial parks dedicated to rare earth work. The country doesn’t just refine—it forges the final forms: magnets, phosphors, catalysts, nanomaterials.

Innovation thrives here: plasma smelting to boost efficiency, bioleaching to cut chemical waste, closed-loop systems that recycle water and reagents, and new alloys that reduce dependence on scarce heavy REEs. The West may mine, but for now, it still ships much of its ore to China to finish the job.

The Environmental Ledger

The industry’s gains come with a price:

• Water contamination from heavy metals and radioactive thorium leaching into aquifers.
• Deforestation and habitat loss from open pits.
• Soil acidification where chemicals seep back into the ground.

Beijing has responded with stricter environmental rules—mandatory impact assessments, chemical controls, and land rehabilitation projects. Yet the hardest problems, like safe radioactive waste storage and the risk of over-mining, linger like a shadow over the sector.

From Market Muscle to Geopolitical Weapon

China’s control over supply gives it extraordinary market power. It can—and has—moved prices and disrupted industries with the stroke of a policy pen. In 2010, amid a territorial spat with Japan, China halted REE exports to that country. Prices soared worldwide.

Neodymium has swung between $50 and $280/kg in the past decade; dysprosium once hit $3,410/kg. Export quotas, selective bans, and licensing keep foreign manufacturers wary and dependent. For the U.S., EU, and Japan, it’s a vulnerability that reaches into defense, energy, and tech manufacturing.

Guarding the Gate: Export Policy and Supply Control

From 2006 to 2015, quotas cut export volumes by up to 40%. Selective bans on key HREEs like dysprosium and terbium protected domestic high-tech industries and gave Beijing a potent diplomatic tool. Even after WTO rulings ended formal quotas, China’s licensing and strategic stockpiling still shape global supply.

In response, other nations are scrambling—restarting mines like Mountain Pass in California and Mount Weld in Australia, forming alliances to share supply, and investing in recycling and substitution.

Greening the Industry—and Closing the Loop

China is now pushing “green mining.” Trials in bioleaching use bacteria instead of harsh chemicals; phytomining coaxes plants to draw REEs from soil. Renewable energy is feeding some mining operations.

On the recycling front, new plants strip REEs from discarded electronics and EV batteries. Techniques like supercritical fluid extraction and plasma arc recycling boost recovery rates and cut waste. Subsidies and tax incentives sweeten the economics. By 2025, recycling could meet a quarter of China’s own REE demand.

Storm Clouds and Horizons

The empire is not without its cracks. Heavy REE reserves are finite, and domestic demand—from EVs, robotics, renewables—is surging. Tighter environmental laws could raise costs, while new supply chains in the U.S., Australia, and Europe threaten market share.

But China is hedging: pouring money into R&D, partnering abroad for mine access, and diversifying its sources. Forecasts suggest ~9% annual growth ahead, with neodymium and praseodymium at the heart of the wind turbine and EV revolutions.

On the other hand, with the Trump administration 2.0 and the launch of Liberation Day, life will never be the same.  The U.S. government just announced another $1 billion into critical minerals (including rare earth elements) via the Department of Energy, while in July, the Department of Defense injected $400 million into the national treasure trove MP Materials for 15% of the equity.   The USA has awakened, and Uncle Sam wants rare earth elements and critical minerals. The unfolding year and into 2026 will be anything but dull. 

But can the Americans get it together to formulate an enduring industrial policy on the critical minerals and rare earth element front?  They’ll need to not only catch up with the Chinese on rare earth refining but also intersect at the future of rare earths---innovation downstream as China is filing far more patents in this area.

The Takeaway

China produces roughly three-quarters of the world’s rare earths and controls nearly all of their processing. It has the largest reserves, the most advanced refineries, and the political will to use them as both economic engine and geopolitical lever. It also carries the environmental scars of that power, even as it experiments with greener ways forward.

The world is learning that in the age of electrification and high-tech everything, the road to the future may well pass through a mine in Inner Mongolia, a refinery in Jiangxi, or a recycling plant in Guangdong. And for now, those roads all lead to China, unless American industrial policy, investment, and resourcefulness can change that trajectory.